Induction power-transmitting device.



A. H. NEULAND, INDUCTION POWER TRANSMITTING DEVICE.

APPLICATION FILED APR. IE. I914.

Patent Id Apr. 17, 1917.

2 SHEETS-SHEET I.

IN V EN TOR.

. WITNESSES A. H. NEULAND. INDUCTION POWER TRANSMITTING DEVICE.

' APPLICATION: FILED APR. l6. l9l4- Patented Apr. 17,1917.

2 SHEETS-SHEET 2.

SN N "INVENTOR. @LWJ 7////////A ll/Illa 1 \w WITNESSES: 44 46% 1 ORNEYS.

ALFONS H. NEULAND, OF BERGENFIELD, NEW JERSEY.

INDUCTION POWER-TRANSMITTING DEVICE.

Specification of Letters Patent. Patented Apr. 1'1, 1917.

Application filed ApriLlG, 1914. Serial No. 182,195.

To all whom it may concern:

Be it known that I. ALroNs H. NEULAND, a subject of the Czar of. Russia, residing at liergenfield, in the county of Bergen and State of Xew Jersey. have invented certain new and useful Improvements in Induction Power-'lransmitting Devices, of which the following is a full, clear, and exact description.

My invention relates to power transmitting devices and particularly to such devices of the electromagnetic or induction type. being adapted to transmit power from one rotating member to another, as from one shaft to another.

An object of my invention is to provide such a device which will be simple, power ful. amlreflicient, and which will produce a change in angular velocity between the driving and driven members.

Another object is to provide means" for varying the speed of the driven member without stopping the driver. Anotherobject is to provide means for reversing the direction of rotatiOn of the driven member.

Still other objects and advantages of my invention will appear from the following description.

In accordance with my invention, I provide means for producing a revolving mag netic flux traversing and coupling a co-axial stator and rotor, the rotor and magnetic flux having a synchronous ratio of rotation at which they rotate at different angular speeds, and I provide an induction winding within the magnetic field, either on the-rotor or stator; which is so arranged that it is not cut by the revolving flux except when the revolving flux and the rotor are out of synchronism under which condition a current is induced in the winding and a torque is developed in the rotor dependent on the amountof slip.

To effect a difference in angular speed between the field and rotor when they are in electrical synchronism', in the preferred the numberof poles of the rotatingfield.

' ffo'ifm therotor and stator are each provided hjaplurality of spaced magnetic conductQrs arranged so that those on the rotor will F f fst ato'r as the rotor rotatesgthe relative'angular speed of the rotor and field being desiiccessively radially aline with those on the termined by the number of magnetic conductors onl'the rotor and by the number of l'clllll ntialpoints of 'alinement of the nductors, which corresponds to" My inventio n also comprehends means for reversing the direction of rotation of the tions so that rither element may be used asv the rotor am either as the stator, or by making certain of the magnetic conductors shiftable circ imferentially on one of the members, thereby reversing the direction of the torque. 4

My inventicn also comprehends means for regulating tilt speed of the driven member. In the preferred form, the revolving magnetic field is produced by a rotating electromagnet mounaed co-axially within the stator and rotor, and the speed control may be obtained by arying the magnetizing current or in any other suitable wa as will readily occur to those skilled in t e art.

My invention also comprehendsvarious other features of construction and arrangements and combinations of parts, as will hereinafter m ore fully appear. r

I shall now describe the embodiments of my invention illustrated in the accompany ing drawings, and shall thereafter point out my invention in claims.

Figure 1 is a transverse vertical section of a machine embodying my inventiomtaken on the line 1- -'1 of Fig.- 2;

Fig. 2 is a central longitudinal vertical section of the same; a I

Figs. 3 and 4 are corresponding views of a. anodified enbodiment of my invention; an

Figs. 5 ant 6 are corresponding views of" another embc diment of my invention.

In the machine illustrated in Figs. 1 and 2, the revolving field is produced by a rotative field mamber 1, mounted co-axially within the an aular' laminated concentric soft iron members 2 and 3, which may be interchangeably med as the rotor and stator, respectively, as will presently appear. field member 1 is fixed upon a central longitudinal'axis 4 and is shown as bipolar, being provided with a suitable field winding 5, the leads t) which enter through a lo tudinal bore or slot in the axis 4, usin cated in dottc d lines, and connect to collector 100 v The r rin'gs 6,whi h are engaged by the brushes of the exterr al or magnetizing circuit/7 in the usual 'ma nner.

'8 and 9 ofthe housing and within the hub 8 portions 10' and 12 of the side plates 10.

and 12, respectively, and within the hub 9" bear concentric'hub ortions 11' and 13 of the side plates 11 an 13, respectively. The axis 4 bears within the inner hubs'10' and 1-1', and thus the rotary members have concentric bearings within the stationary hubs of the housing.

When one of the members 2 and 3 isfixed or stationary, the rotation of the field member will cause the other member to rotate upon its axis, as will be hereinafter described, and the relativedirection of rotation of the two. members isopposite to each other. Inorder to reverse the direction of rotation of the driven shaft 14, therefore,

- clutches are provided for clutching either of the. clutch member 15" the two members at will to the stationary housing, and either to the driven. shaft 14., As shown, there is slidably keyed upon the stationary hub 9 a shiftable clutch member 15 which may be moved into engagement with either the clutch element 16 on the hub 11 of the member 2, or with the clutch element 17 on the hub 13' of the member 3. It is apparent that if the clutch member 15 engages the clutch element 16, the member 2 will be held stationary and the member 3 will be free tp rotate, and similarly if the clutch member 15 engages the clutch ele-.

ment 17, the member 3 will be held stationary and the member-.2 will be free to rotate.

A similar clutch mechanism is provided between the driven shaft 14 and the hubs on the opposite side of the machine. A clutch member15. is slidably keyed on the driven shaft let and is adapted to engage eitherthe clutch element 16' on the hub 10' orthe two members 2 or-3 iscaused to rotate. The

device will be described with the member 3 as the stator and ,the member 2 as the rotor, in which position the clutch member 15 is in engagement with the clutchelement 17 and is in engagement with the-clutch element words, .both clutch members will be shifted to' the left, it being understood that this connection may be readily reversed'which will result in reversing the direction of rotationof the driven shaft.

The inner bet- 3, which periphery of the outer memprovided with shall now term the stator, is a plurality of equally spaced tween the stator and circumferential clutch element 17 on the hub 12, and it is 16, or in other" between the field member and longitudinally extending teeth 18, shown as twenty-four in number, and internally of these teeth and spaced somewhat from their inner ends is a series of twenty-four laminated soft iron bars 18, arranged concentric with the inner ends of the teeth 1-8 and supported upon an annular rib 19 on the side plate 13, the bars 19-being dis osed parallel to and in radial alinement wit the res ective teeth 18.

he member 2, which I shall now call the rotor, is provided on its outer periphery with a series of e ually spaced longitudinally-extending tee h 20 differing in number from those, on the stator and'shown as twenty-six in number, there being only a slight air gap space between the outer ends of the teeth 20 and on the inner faces of the bars 18, and disposed within the space between the teeth 18 and the bars 18 is a series oftwenty-six laminated soft iron bars 20, which arecarried by an extension of the sideplate 10 of the rotor and are arranged in radial alinement with and paral-.

lel to the respective teeth 20. The rotor and stator bars are of width as bers, and their thickness is such that when they are alined they reduce the air gap berotor to a minimum, while it will be observed that when they are in staggered relation, they substantially break the magnetic path between the two members.

The rotor teeth and bars difl'er in number from those of the stator by the number of poles of the field member 1, and it will therefore readil be seen that there are two points of full alinement of the rotor and stator teeth and bars. It evident that with the illustrated construction, the rotation of the '90 a substantially the same the teeth of the respective mam-- rotor with respect to-the stator for a distance will cause the teeth and the bars of the rotortoaline themselves successively with the teeth and bars of the stator, thus causing the progression of the. magnetic path formedby V for one-half of a revolution.- The field member has the same angular speed as the revolving vmagnetic path when the field member is in electrical 'synchronism with the rotor,

In other words, the relative angiilar velocity t e rotor is as 13 to 1, the magnetic paths making 13- complete revolutions to eachrotation of the between the they rotate in rotor, and-the ratio of rotation field member and rotor'when electrical synchronism is therefore 13to 1."

I It will be observed that in addition to the 4 the field and, rotor-rotating in the same direction since the number of teeth and bars 'of'the rotor exceeds that of the stator.

the alinement of the teeth,

magnetic path just described, which includes the ined teeth and bars. acrosstheair gap between the stator and rotor, the rotor also forms a closed magnetic path which is shorter than the ath th'rou h the alined teeth and bars an throught e stator, and the flux will therefore tend to pass throutih I e the "rotor, one half in one direction and other half in the other direction. The flux will take this shorter path when the field member is standing still, since the magnetizing' current is a direct current, irrespective of whether or notthereare inductiorrcoils upon the rotor. When the field member is rotated, however, the flux becomes an alternating one, and it is evident that under that condition an induction coil upon the rotor willtend to choke back the magnetic flux through therotor andto cause the flux to follow the other (path through the alined teeth and. bars an through the stator. An

induction winding is therefore placed in the, construction shown upon the rotor, and this winding is composed of twenty-six short-circuited turns 21, disposed between the respec-' tive rotor teeth 20, andeach turn being-independent of the others and being composed of an external bar laid in between the teeth tated by external means in synchronism with the revolving magnetic field, the -revolving field travels at the same velocity as the revolvin magnetic path and the axial line of the fie d member therefore'maintains-aline- 1 ment with the progressing magnetic-path becurrent therein.

tween the rotor and the stator, andthe alternating magnetix flux, whichis caused to seek the longer path by the inductionjwinding'of the rotor, will pass between the" short-circuited turns of the induction winding with out cutting them and without .inducing a Under that condition, however, as. previously stated, the driven m'emberor rotor will develop no torque, and it; will be seen that the rotor will develop a torque only when it is out'of synchronism with the revolving field. Thisris the condition which always obtains in actual'operation. l'As the field member is rotated and the alternating ma netic flux is thereby produced, the flux will member is in alinemen-t with the alined teeth a and bars.

necessarilypass aroundthe rotor cutting the induction coils 21, in order to reach the alined teeth and bars, at all times except at the instant when the'axial line of the field A Asthealternating flux is thus caused to cut the J short-circuited'turns of the in proportion to its sli induction winding, it induces a current therein and produces a torque in the rotor.

This slip from :ynchronism will increase substantia ly in pr )portion to the load upon the rotor, and it v ill therefore be seen that the torque increases wlth the increase In load. It is manifest that the'fre uencyof alternations of thl" flux through t e shortcircuited turns and hence the E. M. F. in-

duced' therein,is in direct proportion to the slip of the rotor from synchronism, while the strength of ti e current in the coils is proportional to. the E. M. F. and therefore proportional to the slip from synchronism,

.and, furthermore, since the ower of the in-' ductive couple is depen ent u on the strength of the current, it is evi ent that the greater'the 109. l on the rotor and the con sequent slip, the greater. the frequency and strength of the induced current, and hence.

proportionally grt ater within certain limits thetorque of the rotor.-

The speed of the rotor or drivenmember may be regulated i n any suitable way, as by varying the resists ace of the induction winding,'or' varying the exciting current, which latter may be .done by including a rheostat 22 in the exciting circuit.

It is obvious thatif the clutch connec H0118 are reversed, as explained above the member 2 will be held stationary and the ,member 3 will the a become the driven memher which, hOWeYt r, will rotate in the oppcs site directionto that of the member 2. .For

example, as shown in Fig. 1, the member 2 will move in the'aame direction as the field Y member, while th e member 3 will move in the OPPOSltB'dlIGCtIOILtO efie'ct alinement of the successive teeth and bars. If the member 3 be ,used as the iotor, it will .be noted ,that

the synchronous speed of the field member a and thedriven m1 mber'will be 12 to 1, since there are. twenty-i ourteeth on the member 3.

- Thus the torqueiof the driven member is increased up to certain limitslsubstantially from synchronous speed and a very 1 ower ul torque is thus developed, and it is a parent that my invention. hasvarious a aptations for'reducing speed and transmitting power from one rotating member to another, and itis admirably adapted for use in connection with a high speed-steam turbine to reduce its sgebed to a considerably lower value as require propellers on ship s, locomotives, motor-veh cles and the like. If desired, the device may, i

also be employed to step up the speed in which case the rotor becomes the driver and ghee field member becomes the driven mem In the construrtionshown in Figs. 3 and 4, somewhat dlfl arent means are provided for reversin the direction of rotation of the rotor.

nal member 23, Whicheorresponds to. the

l n this construction the extermember 3 pi .the construction above described, is fixed or stationary, and no external stationar housing is therefore required. The stator e ement 23 has thirty-two teeth 24 and bars 24' correspondin to the teeth 18 and bars 18' of Fig. 1. ese bars and teeth are arranged in eight sections of four each, the teeth and bars of each section beingequally spaced and the sections being alternately fixed and circumferentially adjustab'le 'or shiftable, the shiftable sections 25 bein shiftable for a distance equal to one-ha] the pitch of the stator teeth and bars. The teeth 20 and bars 21 of the rotor, all of which are relatively immovable, are equally s aced, and conse uently at two opposite points four teeth an bars of the rotor will be in alinement with those of the corresponding stator sections, as shown in Fig. 3,

1 plates 27 and 28 having direction of rotation of the rotor as the field member rotates will be dependent upon the relative positions of the intermediate. or

' shiftable sections 25 of the stator teeth and bars, since in one position they are ofl's'et oneuarter of a tooth pitch in one direction relative to the rotor teeth and bars, and when moved to their other position, as shown .in dotted lines in Fig. 3, which isone-half a tooth pitch from their first position, they will be offset one-quarter of a tooth pitch in the opposite direction from the rotor teeth and bars. Thus, by merely shifting the mov-" able sections 25, the direction of rotation of the rotor will. be reversed without stopping the driving member.

In the embodiment shown in Figs. 5 and 6, the revolving magnetic flux is produced in a difierent manner than it is in the previous] described embodiments In this embod iment, the revolving field is produced by a polyphase: current, as in the ordinary induction motor, which traverses the annu-- lar laminated stator 26 which is sup orted between the flanged peripheries 0 side central hub-portions within which" bears'the central lo tudinal axis 29 which carries the rotor.

the construction shown, the stator has" an internal laminated separable winding-su porting portion 30', which constitutes t e shorter magnetic path corresponding to the rotor 2 of Fig. 1, and which fits 'snugly' within the stator 26,. although it is apparent duction win thestator circumferentially until the point synchronism, is, there ore, 13 to 1. "The- .coils 21 of the induction winding are arranged around thewind' -supportin ort-ion 30 of the stator bet v een the 8 ive stator teeth, slots 33 being provided outside of the winding-supporting portion 30 for the accommodation. of these induction coils and for the accommodation of the rimary winding, there being twenty-four 001 of the prima winding, or three coils per phase and po e, in the construction shown a fonrhase current being preferably employed.

he arr n ement of the magnetizing or primary win ding is indicated diagrammatically in Fig. 5, although various other well .known forms ofwindmg will readily suggest themselves to those skilled in the art.

-It is now apparent that the alternating flux will tend to flow across the rotor, due to the presenoe of the coils 21 on the stator portlon 30, and that the points of alinement of the rotor and .stator teeth and bars will normall' tend to .follow the "progressive point 0 maximum value of the flux caused by the pro ive point of maximum current as it raverses the stator, and ,to remain in alinement therewith, under which condition the magnetic flux would pass directlyacross the path formed bytheipoints' of alinement of the teeth without cutting the induction coils 21. .When, however, a

load is applied to the rotor and its speed of rotation and ofthe progressive points of alinement is" retarded relative to that of the revolving, magnetic field, the magnetic flux will take its ath and pass through the in- -supporting portion 30-of of alinement is reached, and will thereby induce a current in the induction coils, and

thereby cause the rotor to produce a torque,

which torque, as in the constructions above described, is proportionate within certain 'ts to the extent of slip from synchronism.

Itis obvious that various other modifications lmay be made in the constructions shown in the drawin larlysdescribed within the.

magnetic field cou ling thestator and rotor, said rotati've eld and said rotor when in electrical synchronism having different angular velocities, and an'induction wmdsing disposed within the magnetic field and arranged to be cut bythe flux lines when the rotative field chronism and rotor are out of syn- 2. An induction power transmitting deviee'. comprising a stator member, a rotor member, means for producing a revolving alternating magnetic flux adapted to couple. the stator and rotor members, spaced flux conductors carried-by "the rotor and stator members cooperative to form a revolving path for the flux between the rotor and stator members as the rotor member rotates andone of the members including an annular magnetic path for the fipx between the source of the flux and the revolving magnetic path, and an induction winding disposed around the annular path, whereby when the revolving magnetic path is out of synchronism with the rotor member the flux will flow a corresponding distance through the annular magnetic path and cut the winding and produce a torque. to y An induction power transmitting device comprisin member, space flux conductors carried-by the rotor and stator members cooperative to form a revolvin path for theflux between the rotor an stator members as the rotor member rotates having greater angular velocity than that. of the rotor member,

means for producing a revolving magnetic 'vice comprising a co-axially arrange flux traversin the two members, and an induction win ing disposed within the magneticfield and arranged to be cut, by the flux lines when the revolving magnetic flux and magnetic path are out of synchronism.

4. Aninduction power tranmiittin destator, rotor and rotative field member, spaced magnetic path are out of synchronism.

fluxconductors carried by the rotor and stator members cooperative to form a revolvingpath for the flux between the rotor and stator members as the rotor member rotates havin a greater angular velocity than that of t e rotor and the fieldmember having synchronous speed with the magnetic path, and-an induction winding onr 'one of the members arranged to be cut-by the flux lines when the revolving magnetic flux and 5. An induction power transmitting device comprising means for producing a re-.

- volving magnetic field, a stator arran ed to a be traverse by the magnetic field an having a plurality of circularly arranged spaced magnetic conductors extending substantiall parallel to the axis of the magl a rotor havinga plurality of spaced magnetic conductors adapted to-successively radiall aline with those of the stator andprovi e closed paths forthe magnetic flux as the rotor rotates whereby the a stator member and rotor rotor and the magnetic field have a predetermined relative speed when in electrical synchronism, and in induction winding disposed within the magnetic field ]and arranged to be cut b v the flux lines when the revolving magnetic field and the rotor are out of electrical sy: ichronism.

6. An induction power transmitting de- ,vice comprising a rotative ma rality of spaced Jnagnetic conductors circularly disposed a1 'ound the magnet and extending parallel tc the axis thereof, a rotor having a plurality of spaced magnetic conductors arranged concentric with and adjacent to those of tie stator and adapted to successively radially aline with those of the stator as the rotor rotates and thereby form a revolving magnetic path, whereby the rotor and the magnetic field have apredeterminedrelative speed when in electrical synchronism, the Held and the path having the same angular velocity when the rotor and field arein electrical synchronism, and an induction winding disposed within the: magnetic field and arranged to be cut by the flux lines when th: revolving magnetic field and the rotor me out of .electrical synchronism.

72 An v ce comprising neans for producing a revolving magnetic field, a stator arranged to be traversed by tle magnetic field and having a plurality of circularly arrangedspaced magnetic conductc rs extending'substantially parallel to the axis of themagnetidfield, a rotor having a plurality of spacedtmagneticconductors adapted to successively radially aline with those ofthe stator and provide closed paths for the magnetic fiuxv as the rotor rotates, whereby the rotorv and the magnetic field have a predetermined relative speed when in electrical synchronism, and an indu :tion Winding on the rotor arranged tobe cut by the flux lines When'the, t field and rotor are out of electrical synchro-.

nism and thereby develop a torque.

8. An induction power transmitting device comprising a irotative magnet for producing 'a revolvirg magnetic field, a stator co-axial with the magnet and having a plu- 1 rality of spaced magnetic conductors circus larly disposed at )und the magnet and extending parallel 30 the axis thereof, a rotor having a plurality of spaced magnetic conductors arrang ed concentric Withand adjacent to those of the stator and adapted to successively radially aline with thoseof the stator as the rotor rotates and thereby form a revolving magnetic path, whereby the rotor and the magnetic field have a predetermined r'elat-i re speed when in electrical synchronism, the field and the path having the same angular velocity when the rotor et for pro-. ducing a revolving magnetic eld, a stator co-axial with'the magnet and having a pluinductioi. power transmitting deand field are in electrical synchronism, and

an induction winding on the rotor arranged to be cut bythe flux lines when the field and rotorare out of electrical synchronism and 5 thereby develop a torque. I a 9., An induction power transmitting device comprising means for producing a revolving ma etic field, a stator arra to be traverse by the magnetic field an ha-vconductors adapted to successively radially 15 aline with those of the stator and provide closed paths for the magnetic flux as the retor rotates, whereby the rotor and the 'magnetic field have a predetermined relative speed when in electrical synchronism, and an induction winding on one of the members comprisin a plurality" of short circuited turns on t e member including external and internal portions and successlvely disposed between the said magnetic conductors of the member. V

10. An induction power transmitting device comprisinga rotative ma et for producing a revolving magnetic eld, a stator co-axial with the magnet and having a plurality of spaced magnetic conductors circularly disposed around the magnet and extending parallel to the axis thereof, a rotor having a plurality of spaced magnetic conductors arranged concentric with and adjacent to those of the stator and adapted to successivel radially aline with thoseofthe stator as t e rotor rotates and thereby form a revolving magnetic path, whereby the rotor and the magnetic field have a predeter-V 40 mined relative speed when in electrical synchronism, the field and the'path having the same angular velocity when the rotor and field are in electrical- A induction winding on t e rotor comprising a plurality of short circuited turns on the rotor including external and internal portions and successively disposed between the said vmagnetic conductors of the rotor.-

, 11. An induction power transmitting device comprising means for producing a revolving magnetic field, a stator arran d to be traversed by the magnetic field an having a'pluralit of circularl arrangedspaced magnetic con uctors exten ing substantially parallel to the axis of the magnetic field; a rotor having a plurality of spaced magnetic conductors adapted to successively radially aline with those of the stator and provide closed paths for the magnetic fiux'as the rotor rotates,whereby the rotor and the magnetic field have a predetermined relative speed: when in electrical synchronism, "and means for reversing the direction of rotation ofthe rotor, 66 12. An induction power transmitting de- 1 havin stator'and provide closed paths for the ma nchronism, and an vice comprising means for producing a revolving ma etic field, a stator arran to be traverse I by the magnetic field an having a plurality of circularly arran spaced magnetic conductors extending an antially parallel to the axis of the magnetic field,- a rotor having a plurality of spaced ma etic conductors adapted to successively ra iall aline with those of the stator and provi e closed paths for the magnetic flux as .the rotor rotates, whereby the rotor. and the magnetic field have'a predetermined relative speed when in electrical synchronism, means for reversing the direction of rotation of the rotor, and an induction winding disposed within the magnetic field and arranged to be .cut by the ux lines when the revolvin magnetic field and the rotor are out o synchronism. v

' 13, An induction power transmitting de. vice comprising means .for producing a revolving magnetic field, -a stator arranged to be traversed by the magnetic field and a plurality of circularly arranged space magneticconductors extending substantiall parallel to the axis of the magnetic fie d, and a rotor having a plur lity of spaced magnetic conductors adapted to successively radially aline with those of the netic flux as the rotor rotates, whereb t e rotor and the magnetic field have a p etermined relative speed when in electrical synchronism, .the magnetic cpnductors of one member being arranged 'm a lurality of sections certain of which are re atively circumferentially adjustable, whereby the direction of rotation of the rotor may be reversed. Y Y

14. An induction power transmitting device comprising means for producing a revolving magnetic field, a stator arranged to be traversed by the magnetic field, and having a plurality of circularly arranged spaced magnetic conductors extending substantially parallel to the axis of the magnetic field, a rotorthavinga plurality ofspaced magnetic conductors adapted to successively radially aline withthose of the stator and provide closed paths for the magnetic flux as the rotor rotates,-whereby the rotor and the magnetic field have a predetermined relative speedwhen in electrical synchronism, the magnetic conductors of one member being arranged in a plurality of sections certain'of which are relatively circumferentially adjustable, whereby the direction-of rotation of the rotor may be reversed, and an induction winding disposed within the magnetic field and arranged to be cut by the flux lines when the revolvin magnetic field and .the progressive path o alinement between the stator and the rotor are out of synchronism. i 7

15. An induction ,power transmitting deand the rotor are out of synchronism.

vice comprising means for producing a revolving magnetic field, a stator arran to be traversed by the magnetic field an having a plurality of circumferentially are ranged spaced magnetic conductors extending substantially parallel to the axis of the magnetic-field, the said magnetic conductors being arranged in sections of a similar num ber of equally spaced conductors and each alternate section being "fixed and the intersections being relatively circumferential adjustable a distance equal to one half 1; e pitch of the magnetic conductorsd a rotor having a number of equally space magnetic conductors arranged concentric with and adjacent to those of the stator, and the conductors of therofcr being adapti ed to successively radially aline with those of the successive stator sections and provide closed paths for the magnetic flux as the rotor rotates, whereby the rotor and the magnetic field. have a predetermined relative speed when in electrical SYIlChI'ODlSIIl, the direction of rotation of the rotor being determined by the respective positions of the adjustable stator sections, and an induction winding disposed within the magnetic field and arranged to be cut by the flux lines and develop a torque when the revolving magnetic field and the rotor are out of syn: chronism.

,16. An induction power transmitting device comprising a rotative magnet for producing a revolving magnetic field,,a stator co-axial withthe magnet and having a plurality of spaced magnetic, conductors circularly disposed around the magnet and extending parallel to the axis thereof, a rotor having a plurality of spaced ma etic conductors arranged concentric wit and adjacent to those of the stator and adapted to successively radially aline with those of the a stator as the rotor-rotates, whereby the re tor and the magnetic field have a predetermined relative speed when in electrical synchronism adjustable means for regulating the speed of rotation of the rotor, and an induction winding disposed within the magnetic field and arranged to be cut by the flux lines when the revolving magneticfield 17. An induction power transmitting de; vice comprising a rotative ma et for pro-'' ducing a revolving magnetic eld, a stator co-axial with the magnet and having a plurality of spaced magnetic conductorscircularly disposed around the magnet and extending parallel to the axis thereof, a rotor.

having a plurality of spaced magnet conductors arran' d concentric with and adjacent to those 0 'the stator and adapted to succes-.

sively radially aline with those of the stator as the rotor rotates, whereby the magnet and the rotor have diflr rent angular speeds when in electrical synchz'onism, means for reversing the direction 0:? rotation of the rotor relative to that of the magnet, adjustable means for regulating the s eed of rotation of the rotor, and an inductlon windin disposed withm the magnetic field an arranged to, be cut by the flux lines when the revolving magnetic field and the rotor are out of synchronisn 18. An induction power transmitting device comprisin a rotative velectro-magnet and a source 0 magnetizing current therefor, a stator co-axial with the magnet and having a plurality of spaced magnetic conductors circularly disposed around the magnet and extending parallel to the axis thereof, a rotor having a plurality of spaced magnetic conductors arranged concentric with and adjacent to whose of the stator and adapted to successively radially aline with those of the stator as the 'rotor rotates,

whereby the magni it and the rotor have dif ferent angular s; eeds when in electrical synchronism, mean; for varying the magnetizing current, and an induction winding on the rotor comprisir g a plurality of short circuited turns on the rotor includingexternal posed between the saidmagnetic conductors on therotor.

19. An induction power transmitting device comprising a rotative electro-magnet and a source of magnetizing current there-,

for, a stator co-axpal with the magnet and having a plurality of spaced magnetic conductors circularly disposed around the magnet and extending parallel tothe axis thereof, a rotor having a plurality of spaced magnetic conductors arranged concentric with and adjacent to 1hose of the stator and adapted to success Lvely radially aline with those of the stat )1 as the rotor rotates, whereby the magm t and the rotor have different angular speeds when in electrical syn- I chronism, means 01 reversing the direction of rotation of the rotor relative to that of the magnet, means for varying the magnetizing current, and an induction winding on the rotor comprisin g a plurality of short cir- 'cuited turns onthe rotor including external and internal portions'and successively disposed between the said magnetic conductors on the rotor.

and internal porti )ns and successively disa In witness whereof, I subscribe my signa ture, in the presence oftwo witnesses.

' ALIONSH. NEULAND.

Witnesses:

Vrcron D. Ions'r, Wanoo (JHAPIN. 

